Effect of Fatty Acid Esterification on the Thermal Properties of

Aug 10, 2016 - Department of Chemistry, University of Helsinki, P.O. Box 55, FI-00014 Helsinki, Finland. ‡ Department of Forest ... Department of Ch...
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The Effect of Fatty Acid Esterification on the Thermal Properties of Softwood Kraft Lignin Klaus Asko Yrjänä Koivu, Hasan Sadeghifar, Paula Nousiainen, Dimitris S. Argyropoulos, and Jussi Sipila ACS Sustainable Chem. Eng., Just Accepted Manuscript • DOI: 10.1021/ acssuschemeng.6b01048 • Publication Date (Web): 10 Aug 2016 Downloaded from http://pubs.acs.org on August 12, 2016

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The Effect of Fatty Acid Esterification on the Thermal Properties of Softwood Kraft Lignin Klaus A. Y. Koivu1*, Hasan Sadeghifar2, Paula A. Nousiainen1, Dimitris S. Argyropoulos2,3, Jussi Sipilä1 1

University of Helsinki, Department of Chemistry, P.O. Box 55, FI-00014 University of Helsinki, Finland

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North Carolina State University, Department of Forest Biomaterials, 2820 Faucette Dr., Campus Box 8001, Raleigh, NC 27695, USA 3

North Carolina State University, Department of Chemistry, 2620 Yarbrough Drive, Box 8204, Raleigh, NC 27695, USA *

Email address of corresponding author: [email protected]

ABSTRACT Esterification of kraft lignin opens up its potential for thermoplastic applications either on its own or as a component of polymer blends. In this effort we have investigated the selectivity of softwood kraft lignin toward esterification via acylation. LignoBoost kraft lignin was esterified with acetyl (C2), octanoyl (C8), lauroyl (C12) and palmitoyl (C16) chlorides at various molar ratios

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with respect to the total hydroxyls present. Quantitative

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P NMR spectroscopy, Fourier

Transform Infrared Spectroscopy (FTIR) and Gel Permeation Chromatography (GPC) were used to evaluate the selectivity and efficiency of these reactions on the various hydroxyl groups present. The C8-C16 acyl chlorides showed distinct enhanced reactivity toward the aliphatic hydroxyl groups, whereas C2 acyl chloride was found to react uniformly with any available OH irrespective of their chemical nature. The effects of long chain acylation on the polymer and material properties were also examined using solution viscosity, thermal and rheological measurements. Polymer blends were also produced and studied by melt extrusion. The long aliphatic chains when installed on the lignin displayed peculiar association effects in solution and enhanced the melt flow characteristics of the lignin-polymer blends.

KEYWORDS Softwood kraft lignin, Fatty acid esterification, Methylation, Characterization, Quantitative

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P

NMR, Thermal and rheological properties, Polymer blends

INTRODUCTION Lignin is an amorphous polyphenol found in plant cell walls. Native lignin has a random, three-dimensional structure created via an enzyme-mediated dehydrogenative polymerization of phenyl propanoic precursors such as coniferyl, sinapyl and p-coumaryl alcohols.1 Softwood trees contain about 28 mass-% of lignin composed of over 95-% 4-hydroxy-3-methoxy (guaiacyl) and traces of p-hydroxyphenyl units.2 The main linkages between the phenylpropane units in softwood lignin (about 45 % of all C9structures) are aryl-alkyl ethers, or β-0-4' bonds.3 During the industrial kraft pulping process that

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is aimed at delignifying wood for cellulose production, most of the β-0-4' linkages are cleaved to yield large amounts of small phenolic compounds.4 Under kraft process conditions, this material forms highly condensed structures with enol ether and stilbene linkages as well as various types of carbon-carbon linkages. Furthermore, these so called "kraft lignins" (spent liquor lignins, or black liquor lignins) possess various aliphatic hydroxyls, methoxyls, catechols, some carboxyl groups and sulfur bridges.5,6 Marton in 1971 proposed a tentative structure for softwood kraft lignin (Scheme S1) admittedly in need of serious revision.7 In the United States, the kraft pulping processes accounts for more than 85 % of wood pulp production with 56 million tons of pulp produced in 2006.8 However, most of the available lignin is not isolated, but provides a major source of energy for pulp mills. Only about 1 million tons per year (2 %) is actually commercialized.9 Recent technology developments have brought about the design of the LignoBoost process which offers granular kraft lignin of good quality with lower costs and concomitant benefits of higher pulp production. These lignins contain typically 0.3-1.2 % ash and 1-3 % sulphur.10 Unmodified kraft lignin has been viewed as a source of chemicals and carbon fiber from biorefineries,11 and as a component of polymer composites.12 However, when unmodified it is poorly soluble in organic solvents and resists thermal flow when heated. Thermal flow is necessary for melt-processing in the production of polymer blends.13 Furthermore, unmodified pine kraft lignin starts decomposing at temperatures of around 120 °C through evolution of formic acid, formaldehyde, sulfur dioxide, carbon dioxide and water, and breakdown of bonds in the phenyl propane side chains.14 This has been recently evidenced in experiments where softwood kraft lignin was thermally heated into its Tg.15

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Derivatization of kraft lignin opens up its potential for thermoplastic applications either on its own or as a component of polymer blends.16-19 Most widely studied methods are based on hydroxyl propylation and esterification. In esterification most of the published papers have utilized short chain fatty acids. Lignin acetylation offers enhanced solubility characteristic useful for NMR spectroscopy and GPC lignin structural analyses.20 Lewis and Brauns made a range of C2-C18 esters and found them usable as mold lubricants and plasticizers for plastics.21 Pruett et al. used C2 to C4 esters for preparation of colored polyesters for plastic containers that show low light transmittance in the UV range.22 Tinnemans and Greidanus tested C2, C7, and C18 acylated lignins as part of maleic anhydride copolymer blends in water swelling materials. The esters functioned also as components in blends of recycled low-density polyethylene and polypropylene.23 Thielemans and Wool examined how C4 esters improve resin and fiber compatibility in thermoset composites.24 Mariotti et al. used C4 and C18 esters to make biocomposites of high-density polyethylene.25 Tamminen et al. applied tall oil fatty acid (C16, oleates, linoleates) esters as barrier materials in fiber-based packaging.26 Hult et al. measured the properties of C12 and C16 ester coated fiberboard for packaging applications.27 Pawar et al. synthesized C18 lignin esters and studied thermal properties of polystyrene blends.28 Esterification of lignin can be achieved in various ways. The oldest references reported mixtures of acyl chloride with pyridine or triethylamine.21 A model compound study has shown pyridine catalysis to favor aliphatic hydroxyl groups, and triethylamine to favor phenolic hydroxyl groups.29 Glasser and Jain used either equimolar pyridine:acyl anhydride, or acyl anhydride:acyl acid with sodium alkanoate as catalyst.13 Thielemans and Wool used acyl anhydride:acyl acid (1:1) with 1-methylimidazole (1-MIM) as catalyst.24 Pyridine-catalyzed reactions have been generally slow (up to 48 hours) whereas 1-MIM offered complete

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esterification in approximately one hour.30 Transesterification can be used to add lignin to polyesters. Pruett et al. produced poly(ethylene terephthalate) (PET) by reacting dimethylesters of dicarboxylic acids with ethylene glycol and C2-C4 esterified lignin.22 Recently, Hulin et al. used lipase catalyzed transesterification to react kraft lignin with ethyl oleate in ionic liquids.31 For the elucidation of the material properties of lignin and its derivatives for different technical applications, a thorough understanding of the effects affecting lignin thermal properties are required.32 In this study we have systematically examined the effect of acid chain length and degree of substitution on the structure and thermal properties of technical softwood kraft lignin esters. For this purpose, 20 ester samples using a set of four acids (C2-C16) with five various loadings (10-100 mol-%) were prepared. For melt flow studies an additional set of 4-O methylated esterified SWKL lignins were synthesized. The structural determination was performed by FTIR, GPC and

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P NMR, and the thermal properties were determined by DSC

and TGA. In general, esterification with long-tail fatty acids was found to significantly lower the Tg's of SWKL esters even at lower degrees of substitution and to enhance the melt flow properties of lignin-polyethylene blends. Also, new information to understand the reactivity of different types of phenolic hydroxyls in kraft lignins in the esterification process was obtained. To our best knowledge, no previous systematic study with such a big dataset on kraft lignin esterification has been previously performed.

EXPERIMENTAL SECTION Materials and Methods Chemicals Softwood LignoBoost kraft lignin (SWKL) was obtained from Stora Enso Oyj, Finland. The lignin was dried for 2 hours under high vacuum at 50 °C before use. Acetyl

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chloride (C2) (≥99 %), octanoyl chloride (C8) (99 %), lauroyl chloride (C12) (98 %), and palmitoyl chloride (C16) (98 %) were obtained from Sigma-Aldrich and were used as received. Dimethyl sulphate (≥99 %) was obtained from Aldrich. Polyethylene was obtained from SigmaAldrich. Pyridine (99.8 %), tetrahydrofuran (THF) (≥99.9 %), dimethylformamide (DMF) (99.8 %), and Celite 535 were obtained from Sigma-Aldrich. All solvents were used from freshly opened bottles. Methods Partial esterification of softwood KL Typically, 5.0 g lignin (containing 6.67 mmol/g of total phenolic and aliphatic hydroxyls measured by quantitative 31P NMR analysis) was dissolved for 30 minutes in 30 mL tetrahydrofuran, 7.5 mL dimethylformamide, and 3.9 mL pyridine (9.4 mmol/1 g lignin) at 60 °C under argon. Different amounts of acyl chlorides (C2, C8, C12, C16, 0.66-8.57 mmol/g lignin, 0.1-1.3 equivalents vs. total aliphatic and phenolic hydroxyls, Table 1) were injected with a syringe (Scheme 1 (A)). The reaction was kept for 48 hours at 65 °C under argon with efficient stirring. The isolation of the esterified lignin was performed by adding Celite 535 into the reaction solution in sufficient amounts to make the mixture powdery, precipitating by adding water and washing with water and ethanol (cooled to 0 °C) to yield dry powder. Celite was removed by Soxhlet extraction using THF. The product was dried on a watch glass after most of the solvent was removed. The masses of products were 4-8 g (theoretical masses 5-13 g, yields 60-80 %). Complete and selective methylation of the phenolic OHs of softwood KL The lignin (50 g, containing 4.40 mmol/g of total phenolic hydroxyls measured by quantitative 31P NMR analysis) was fully methylated using excess dimethyl sulphate (3.8 times vs. total phenolic hydroxyls) following the procedure by Sadeghifar et al. (Scheme 1 (B)).33 The product was precipitated by adding sufficient amount of 2M HCl (pH 2-3) and washed with excess water up to 6 times using 6 ACS Paragon Plus Environment

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efficient vacuum filtration to reach neutral pH. The mass of product was 48 g (yield 90 %). The product was analyzed by quantitative

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P NMR for free hydroxyls (2.3 mmol/g aliphatic, 0.15

mmol/g condensed phenolic, 0.02 mmol/g noncondensed phenolic) and used in melt extrusion as a matrix. Partial methylation of softwood KL followed by complete esterification First, the lignin (50 g, containing 2.27 mmol/g of aliphatic hydroxyls and 4.40 mmol/g of total phenolic hydroxyls measured by quantitative 31P NMR analysis) was methylated using equimolar amount (per total phenolic hydroxyls) of dimethyl sulphate in aqueous 0.8 M NaOH (Scheme 1 (B)). After workup as detailed in complete methylation synthesis, the product was analyzed by quantitative

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P NMR for free hydroxyls (2.2 mmol/g aliphatic, 2.2 mmol/g total phenolic, 1.2

mmol/g condensed phenolic, 1.1 mmol/g noncondensed phenolic). The mass of product was 47 g (yield 91 %). Next, the dried powder (20 g) was subjected to full esterification by adding excess fatty acid chlorides (C2, C8, C12, C16, 5.72 mmol/g, 1.3 equivalents vs. total remaining aliphatic and phenolic hydroxyls) as before (Scheme 1 (A)). After workup as detailed in the partial esterification synthesis, the products were analyzed by quantitative 31P NMR for free hydroxyls (